Miller and Levine Biology Ch 12
Miller and Levine Biology textbook Chapter 12 study cards
Terms in this set (48)
process where 1 strain of bacteria is changed by genes from another strain of bacteria
virus that infects bacteria
bacteriophage attaches to the surface of the bacterial cell and injects its genetic information into it. The phage DNA is incorporated into the bacterial DNA and the phage uses the bacterial cell to produce new bacteriophages.
how bacteriophages work
transmit genetic information in a cell
DNA's roles (3)
foremost job: contain all instructions for determining what and organism will be and the process of developing from a single cell to an adult.
before a cell divides it must make complete copy of every gene for the new cell.
genes must be transmitted from one generation to the next.
DNA stands for ___
nucleotides joined into long strands/chains by covalent bonds.
DNA is made of ___
Nucleic acids are made of ___
5 carbon sugar
3 basic components of nucleotides
term for a base that contains nitrogen
DNA's 4 nitrogenous bases
the sugar group of one nucleotide and the phosphate group of the next nucleotide.
In DNA, covalent bonds form between ___
[A]=[T] and [C]=[G]; in DNA, the amount of adenine and thymine found are equal and the amount of cytosine and guanine are equal.
the shape of DNA; 2 DNA molecules twist around each other like a ladder.
double helix explains
1.)Chargaff's rule of base pairing,
2.)how two strands are held together, and
3.)how DNA can function as a genetic carrier
2 strands of DNA run in opposite directions
holds 2 strands of the double helix together;
hydrogen bonds form only between certain nitrogenous bases. These weak bonds allow the structure to separate.
Why is hydrogen bonding in DNA important?
What do we call the following:
adenine pairs with thymine
cytosine pairs with guanine
Each base on one strand pairs with only one base on the opposite strand; each strand has information necessary to reconstruct the other half (strands are complementary)
how does base pairing in double helix explain how DNA can be copied?
a copying process which duplicates the DNA
a process (mediated by enzymes) which separates the two strands of DNA, allowing 2 replication forks to form.
unzipping the dna
breaking the hydrogen bonds
unwinding 2 strands
role of DNA Helicase enzymes in replication
enzyme that joins individual nucleotides to produce and proofread a new DNA strand.
dna at tips of chromosomes which is difficult to replicate
an enzyme which helps replicate the telomere region by adding short repeated DNA sequences to telomeres;
helps prevent genes from being damaged or lost
beadlike structures of DNA and histones
in the S phase
DNA replication occurs when?
prokaryotic DNA replication
starts in a single spot and goes around in 2 directions until the entire chromosome is copied
eukaryotic DNA replication
begins at many different spots on the DNA molecule and proceeds in 2 directions until the entire chromosome is copied
Single - stranded binding protein
proteins that bind to the freshly split DNA molecule to keep the two strands apart.
Strand of freshly copied DNA which is continuously made
Strand of freshly copied DNA which is discontinuously made - resulting in fragments of DNA which will need to be strung together later.
Disjointed pieces of DNA which are created on the lagging strand.
Alfred Hershey and Marsha Chase
Used radioactive materials on bacteriophages to see which material got passed on to bacteria cells, DNA or proteins. Found that DNA was the molecule responsible.
Scientist who, with his team, found the molecule which results in transformation by meticulously destroying one molecule at a time.
Scientist who studied the r-strain and s-strain of bacteria and how it influenced mice.
What is the image an example of?
What would the complementary DNA strand be if the original strand's sequence is CGTA?
Scientist who conducted x-ray diffraction on DNA to discover it was a double helix shape
Watson and Crick
Scientists who first build a proper model of the DNA molecule
Scientist who discovered the amount of adenine and thymine are always equal, as well as the amounts of guanine and cytosine.
The shape of a bacteria cell's DNA
In the cytoplasm
Where a bacteria cell's DNA can be found
in the nucleus
Where a eukaryotic cell's DNA can be found.
Adenine and Guanine
The bases known as the purines.
Thymine and Cytosine
The bases known as the pyrimidines.